Solution for and method of coating ferriferous surfaces



United States Patent The present invention relate to the art of producing a phosphate conversion coating on a ferriferous metal surface and is particularly concerned with that type of conversion coating which is produced by treating the surface of the metal with alkali metal phosphate solutions.

In this disclosure the term alkali metal phosphate is to be understood as including both sodium and potassium phosphates as well as ammonium mono and ammonium dihydrogen phosphates.

In this art as heretofore practiced the alkali metal phosphate coating baths have been employed as aqueous solutions having pH values ranging from approximately 3.2 to 6.2 although, as a general rule, a somewhat narrower pH range has been employed, say from about 4.7 to 6.0. Furthermore, it has been customary practice to include one or more of the so-called accelerating agents such, for example, as chlorates, nitrates, nitrites and peroxygen compounds which, as is well known, operate to reduce the time required for coating formation.

In prior practice another factor has also been important and that is that the type of solutions just described have had to be heated to temperatures ranging from about 170 to l80 F. in order that they may produce the desired coatings within a reasonable period of timesay from 1 to 3 minutes.

Other problems have also arisen in connection with the practices of the prior For instance, while nitrite ion has been recognized as an accelerating agent in baths 0f the type described, its use, generally speaking, has been restricted to combinations with other well known accelerators. This restricted use of the nitrite ion is a reflection of certain inherent disadvantages associated with its behavior in coating solutions of this type. For example, where an insufficient amount of accelerator is employed, no apparent coating is produced on ferriferous surfaces. Conversely, if too great an amount is employed a phenomenon known in the art as white spot is produced on the metal being treated and, eventually, no coating of any appreciable value can be obtained.

With nitrite accelerated alkali metal phosphate coating solutions it has been observed also that the coatings produced are lighter in weight by as much as 20% to 25% as compared to coatings resulting from the use of ohlorates or peroxygen compounds as accelerators, which lighter weight coatings are not as suitable for pre-paint use since their corrosion resistance is definitely inferior to that of heavier coatings.

More recently it has been found that the use of bromates as accelerating agents not only yields heavier coating weights than are obtained with nitrites but also permits the use of lower reaction temperatures on the order of 150 to 160 F., although some sacrifice in coating weight results from the use of such lower bath temperatures. However, brornate accelerated baths often produce coatings which are mottled or otherwise uneven in appearance, which uneven appearance frequently affects the appearance of the treated metal surface after it has been given a final siccative finish such as paint or the like.

With all of the foregoing limitations of the prior art in mind the principal object of the present invention may be said to reside in the provision of an improved nitrite accelerated alkali metal phosphate coating process by means of which it is possible to produce, on ferriferous metal surfaces, highly corrosion resistant and extremely effective paint bonding coatings at lower temperatures than has been possible heretofore.

A concomitant object of this invention is to provision of a solution for and a method of applying phosphate conversion coatings to ferriferous metal surfaces of more uniform appearance and of greater weight than has ever been possible heretofore with any of the nitrite accelerated alkali metal phosphate coating baths familiar to the art.

How the foregoing objects and advantages as well as others may appear hereinafter are attained will become apparent in connection with the following description.

The present invention is based upon the discovery that if at least 0.05 gram/liter of a heterocycle compound selected from the group consisting essentially of melamine, 3-amino-l,2,4-triazole, imidazol, succinimide and 2-oxazolidone is added to a nitrite accelerated alkali metal phosphate coating solution having a pH of [from 4.0 to 5.8, such solution can be employed as a coating bath in the treatment of ferriferous metal surfaces to produce an extremely uniform, highly corrosion resistant coating of substantially greater weight than heretofore possible in this art even when customary or normal treating cycles of l to 3 minutes are employed and, furthermore, that these improvements in result can be obtained at appreciably lower coating bath temperatures than have ever been practical heretofore.

As noted heretofore, at least 0.05 gram/liter of the heterocyolic compound from the class described must be incorporated into the coating solutions of this invention. Where less than this minimum amount is utilized no appreciable coating will result and the benefits of this invention will be completely lost.

Although use of as little heterocyclic compound as 0.05 gram/liter yields the desired coatings at lower operating temperatures, it has been discovered that 0.1 gram/liter is a preferred minimum in order to insure, at all times throughout operation of the bath, that a sufficient amount of this additive is present.

So far as the upper limit of heterocyclic compound is concerned it has been found that there is no apparent deleterious effect from the use of as much as 30 grams/ liter of these compounds. Use of even higher amounts thereof are limited in some instances by solubility considerations, but Where a particular heterocyclic compound falling within the class listed hereinabove is soluble in an infinite degree, such as for example, 3-amino-1,2,4- triazone, no limitation on the amount used has been found. In the interests of economy, however, it is preferred not to exceed about 10 grams/liter of heterocyclic compound in the coating solutions of this invention.

With respect to the amount of nitrite ion (calculated as N 0 which should be utilized in association with the heterocyclic compounds above described, certain rather unexpected factors have been discovered which will now be described. Where the quantity of heterocyclic compound employed in the solution ranges from 0.05 to approximately 1 gram/liter it is essential that the grams of nitrite ion per liter of coating solution should lie within the range determined by the following equations:

A. For the minimum amount of N 0.05 Molecular weight of heterocyclic compound used B. For the maximum amount of N0 1 Molecular weight of heterocyclic compound used Where the quantity of heterocyclic compound employed is greater than approximately 1 gram/ liter it is necessary to employ not less than the minimum quantity of nitrite ion as calculated by Equation A, while at the same time the maximum quantity of N0 may go well beyond the amount which is determined by Equation B. Indeed, just as soon as more than approximately 1 gram/liter of heterocyclic compound is employed there seems to be no need to limit the quantity of nitrite ion which can be utilized in the bath and as much as 10 grams/liter of N0 has been found to produce completely satisfactory results. The only limitation on the upper quantity would seem to be imposed by considerations of economy and unnecessary wastage of this salt. Furthermore, I have found that use of relatively large excesses of nitrite ion relative to the amount of heterocyclic compound employed where the content of the latter is approximately 1 gram/liter or more has, somewhat surprisingly, made it possible to greatly increase coating weights without impairment of their quality. In short, with my process I find that coating weights can be substantially increased by increasing the quantity of nitrite employed although this advantage cannot be realized to its fullest extent except where the bath contains more than approximately 1 gram/liter of the heterocyclic compound.

To refer again to Equations A and B, in situations where the quantity of heterocyclic compound lies between 0.05 and 1 gram/liter the following specific example is suggested. Where melamine is the heterocyclic compound employed and is utilized in an amount of from 0.0 5 to 1 gram/liter, then the amount of nitrite ion which is required must lie between the limits determined by substituting the molecular weight of melamine (126.13) in the equations. This will give a range for the nitrite (N0 of 0.02. to 0.36 gram/liter of coating solution. However, where the amount of heterocyclic compound employed is greater than 1 gram/liter it is only necessary to be sure that at least 0.02 gram of N0 per liter is employed, although many times more than the maximum of 0.36 gram/liter is entirely practical and, as stated above, as much as grams/liter of N0 have been found to produce completely satisfactory results. This fact was completely unpredictable insofar as prior art experience with nitrite accelerated alkali metal phosphate coating solutions is concerned, and I have discovered that by increasing the nitrite content coating weights of more than twice that normally realized heretofore can be obtained with my invention.

The nitrite ion may be introduced into the alkali metal phosphate coating solution as a salt, such, for example, as an alkali or alkaline earth metal salt. Due to commercial availability the sodium salt is preferred. However, the only limitation cn the salt used is that the cation portion thereof exhibit no deleterious effect upon the coating reaction.

So far as control over the nitrite content of the improved phosphate coating solutions of this invention is concerned, this is readily accomplished either by a permanganate titration in acidic medium or by an iodometric titration according to well established art practices.

With respect to control of the heterocyclic compound content of my improved coating solutions, it has been found that a visual control is both adequate and reliable so long as the coating solution contains nitrite ion and is not deficient in alkali metal phosphate ion or pH. For

example, where coating quality begins to deteriorate as evidenced by thinner coatings being produced on ferriferous surfaces, a nitrite titration is immediately taken and, if such titration shows the presence of nitrite ion, it is only necessary to add at least 0.05 gram/liter of a heterocyclic compound in order to restore the bath to its original and desired coating ability. Where the nitrite titration shows a deficiency of this accelerator, it is preferred practice to add nitrite without adding heterocyclic compound, since results with this process show that the heterocyclic compounds are not consumed in the coat ing reaction, and that the only loss thereof is through entrainment or drag-out during coating operations.

As noted hereinabove, the alkali metal phosphate coating solutions of this invention must be maintained within a pH range of 4.0 to 5.8. Where pH values of less than 4.0 are employed the solution exhibits an undesirable etching action on the ferriferous metal surfaces thereby impairing coating formation. Conversely, where the solution pH is permitted to rise above about 5.8, the coatings produced will be found to be thin and powdery, while still further pH increases will result in no coating being produced upon the metal surfaces. A preferred pH range for operating the process of this invention has been found to be from 4.5 to 5.7 since optimum coatings are produced within this narrower pH range.

Adjustment of the coating solution pH may be made, where needed, by the addition of small increments of either phosphoric acid or sodium hydroxide according to well established art practices.

One of the outstanding improvements derived from the process of this invention is the ability to obtain coatings on ferriferous metal surfaces at temperatures of from to F. As noted hereinabove prior usage of alkali metal phosphate coating solutions necessitated the employment of coating temperatures of to 180 F. in order to obtain satisfactory results. The reduced operating temperatures made possible by the improvements of this invention represent considerable economic advantages to the coating industry.

The 120 to 150 F. operating temperature range applies to dip, spray or roller coating applications and, while no harmful results are obtained by use of coating temperatures above 150 F., that is temperatures of 170 to 180 F., or even higher, excessive temperatures have been found to result in reduced coating weights, and such temperatures are completely unnecessary and represent an economic waste when utilizing the present process. Temperatures below the minimum of 120 F. should not be used since it has been found that the desired coating weights will not be obtained at such low temperatures within reasonable operating cycles.

So far as the length of time of treatment is concerned, it has been found that the coating cycle will provide the desired coatings when operated for as little time as 30 seconds to as much time as 5 minutes. However, the pre ferred operating cycle is from 1 to 3 minutes utilizing a temperature of from about 135 to 145 F. Use of lower treating temperatures will necessitate longer contact times, While, conversely, use of slightly higher treating temperatures will require shorter contact cycles.

In order to contrast the results obtainable with the process of the present invention with results obtained from a typical prior art nitrite accelerated alkali metal phosphat coating solution, the following tests were conducted:

A tap water solution was prepared containing, per liter, 10 grams of monosodium phosphate (NaH PO The pH of this solution was 5.2.

Portions of this alkali phosphate solution were then utilized for the treatment of clean, cold-rolled steel panels utilizing contact cycles of 2 minutes and coating temperatures of 140 F., except for Example #2 which utilized a temperature of R, which latter temperature is typical of that used in the prior art. Hetcrocyclic compounds and nitrite accelerator (as NaNO were added to these solutions prior to coating utilization in accordance with the following table:

Following coating each panel was subjected to an immediate water rinse after which a dilute chromic acid rinse was utilized in accordance with well established art practice. A baking enamel was then applied to these panels, and following a curing cycle they were subjected to standard salt spray tests (ASTMB11757T). A resume of the corrosion resistance of these panels is presented below in Table II.

Table II Corrosion Results After 336 hrs. (ASlM-Bll757l) Average Rating Panels from Example From the foreging tests it is readily apparent that the use of nitrite accelerated alkali metal phosphate coating solutions, which solutions also contain an amount of heterocyclic compound from the class described, produced coatings of higher weight and superior corrosion resistance at lower temperatures than could heretofore be obtained with nitrite accelerators.

It is within the purview of this invention to employ an amount of wetting agent in the improved alkali metal phosphate coating solutions of this invention, if desired, since, as is well known in the art, such wetting agents serve to improve the solutions ability to wet thoroughly the entire metal surfaces introduced therein.

I claim:

1. In the art of forming a phosphate conversion coating on a ferrifcrous metal surface wherein an aqueous alkali metal phosphate coating solution is applied to the surface to form the coating: the method which comprises including in the coating solution, as addition agents, the following ingredients:

(1) from 0.05 to l gram/liter of a heterocyclic compound selected from the group consisting of melamine, 3-amino-1,2,4-triazole, imidazol, succinimide and 2-oxazolidone and (2) nitrite ion (calculated as N0 within the range determined by the following equations:

6 and maintaining the temperature of the solution at not less than F.

2. The method of claim 1 wherein the temperature of the solution is maintained at from 120 F. to 150.F.

3. The method of claim 1 wherein the temperature of the solution is maintained at from F, to F. and the treatment continued for from 1 to 3 minutes.

4. The method of claim 1 wherein the pH is maintained from 4.5 to 5.7.

5. In the art of forming a phosphate conversion coating on a ferriferous metal surface wherein an aqueous alkali metal phosphate coating solution is applied to the surface to form the coating: the method which comprises including in the coating solution, as addition agents, the following ingredients:

(1) upwards of 1 gram/liter of a heterocyclic compound selected from the group consisting of melamine, 3-amino-l,2,4-triazole, imidazol, succinimide and 2-oxazolidone and (2) a quantity of nitrite ion (calculated as N0 which is not less than 0.05 Molecular weight of heterocyclic compound used maintaining the pH of said solution at from 4.0 to 5.8; and maintaining the temperature of the solution at not less than 120 F.

6. A bath for use in forming a phosphate conversion coating on a ferriferous surface, said bath consisting essentially of:

( 1) an aqueous alkali solution of phosphates from the class which consists of sodium, potassium, and ammonium mono and dihydrogen phosphates in coating producing concentration and (2) the following ingredients as addition agents:

(A) not less than 0.02 gram/liter of nitrite ion (calculated as N0 and (B) not less than approximately 1 gram/liter of heterocyclic compound selected from the group consisting of melamine, 3-amino-1,2,4-triazole, imidazol, succinimide and 2-oxazolidone.

7. A bath for use in forming a phosphate conversion coating on a ferriferous surface, said bath consisting essentially of:

(1) an aqueous alkali solution of phosphates from the class which consists of sodium, potassium, and ammonium mono and dihydrogen phosphates in coating producing concentration and (2) the following ingredients as addition agents:

(A) from 0.05 to 1 gram/liter of a heterocyclic compound selected from the group consisting of melamine, 3-amino-1,2,4-triazole, imidazol, suc cinimide and 2-oxazolidone and (B) nitrite ion (calculated as N0 the quantity of ion being within the range determined by the following equations:

For the minimum amount of N0 Molecular weight of heterocyclic compound used References (Iited in the file of this patent UNITED STATES PATENTS 2,766,153 Russell Oct. 9, 1956 2,766,154 Russell Oct. 9, 1956 2,769,737 Russell Nov. 6, 1956 UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION Patent N00 3, 129, 122 April 14, 1964 Edward A Rodzewich It is hereby certified that error appears in the above numbered patent requiring correction and that the said Letters Patent should read as corrected below.

Column 1, line 10, for "relate" read relates column 2, line 11, for "to" read the line 19, after "others" insert which line 22, for "heterocycle" read heterocyclic line 36, for "heretofore" read hereinabove same column 2, line 57, for "triazone" read triazole column 5, line 41, for "foreging" read forc going Signed and sealed this 4th day of August 1964;

(SEAL) Attest:

EDWARD J. BRENNER Commissioner of Patents ERNEST W. SWIDER' Attesting Officer 

1. IN THE ART OF FORMING A PHOSPHATE CONVERSION COATING ON A FERRIFEROUS METAL SURFACE WHEREIN AN AQUEOUS ALKALI METAL PHOSPHATE COATING SOLUTION IS APPLIED TO THE SURFACE TO FORM THE COATING: THE METHOD WHICH COMPRISES INCLUDING IN THE COATING SOLUTION, AS ADDITION AGENTS, THE FOLLOWING INGREDIENTS: (1) FROM 0.05 TO 1 GRAM/LITER OF A HETEROCYCLIC COMPOUND SELECTED FROM THE GROUP CONSISTING OF MELAMINE, 3-AMINE-1,2,4-TRIAZOLE, IMIDAZOL, SUCCINIMIDE AND 2-OXAZOLIDONE AND (2) NITRITE ION (CALCULATED AS NO2) WITHIN THE RANGE DETERMINED BY THE FOLLOWING EQUATIONS: 